KR20050036422A - Tunnel digging method using sheet pile - Google Patents

Abstract

The present invention provides a simple structure to excavate the tunnel in a non-adhesive manner using a sheet pile, the process is inserted so that each flange is interconnected to form a plurality of sheet pile in a loop in the ground And excavate the tunnel under the inserted seat piles, and then bury the tunnel structure in the space of the excavated tunnel, and separate the respective seat piles forming the loop after the tunnel structure has been buried. After the process, the process is carried out to the outside for recycling.

According to the present invention, the loop of the tunnel is formed by the coupling between the flange portions using the sheet pile in the non-adhesive manner without being influenced by the lipid, so that the assembly time is simple and the construction time can be shortened. Due to the strong connection structure, it has a useful effect to improve durability against soil pressure.

Description

Tunnel excavation method using sheet pile {TUNNEL DIGGING METHOD USING SHEET PILE}

The present invention relates to a tunnel excavation method using a sheet pile, in particular a tunnel using a sheet pile to securely support the excavation ground during construction while employing a non-adhesive pipe loop method using a plurality of sheet piles that can be mutually coupled It is about an excavation method.

In general, various tunnel structure construction methods are used to construct structures such as underpasses and tunnels, and typical tunnel structure construction methods include tunneling by completely attaching the ground of a place to construct tunnel structures such as underpasses and tunnels. After the construction of the structure, the open trench method (hereinafter referred to as OTM) to cover the soil deposited on it and construct the tunnel structure, and the shield tunneling machine without opening the land of the place to be constructed There is a Tunneling Boring Method that constructs a tunnel structure in the formed tunnel after the tunnel is formed in the non-attached manner using the.

In addition, the pipe roof method is to construct a tunnel in a place where tunnel excavation, such as under a road or railway rail, is difficult, while constructing the underground structure under the upper part while supporting the upper soil layer using a pipe. Etc.

Each method described above has its advantages, but the Open Trench Method (OTM) is not only restricted by the construction structure of the ground but also obstructs the traffic flow on the ground. In addition, since the tunnel boring method (TBM) has a structure that can only build a circular tunnel structure or arched tunnel structure mainly, to construct a rectangular tunnel structure, a round or oval of diameter larger than the diameter of the tunnel structure There was a drawback to construction.

Accordingly, the pipe loop method is mainly employed to excavate tunnels in places where excavation is difficult, such as soils with poor geological conditions, thin ground toffee thickness, or obstacles to ground traffic. The loop method is a method of increasing the stability of the ground by inserting a pipe, which is a stress material, in an arc shape.

As an example of the pipe loop method, as shown in FIG. 1, a plurality of pipes 10 are pressed into the ground G to the outside of the portion where the tunnel structure is to be inserted to form an arch structure, and the loop R The reinforcing material 30 to reinforce the connection of the pipes 10 to form a is coupled in a belt shape to support each of the pipes 10 from the bottom.

The excavation method inserts the steel pipe 10 into the ground around the predetermined cross section of the tunnel T before the excavation of the tunnel T. Then, the steel pipes 10 are mutually fixed. Arranged at intervals to form a loop (R).

Thereafter, the earth and sand under the roof R is excavated using an excavator (not shown), and a tunnel structure (not shown) is installed in the excavated space.

After the tunnel structure is installed and in place, the steel pipe 10 can be taken out again and recycled.

Since the pipe loop method is not a structure in which a plurality of steel pipe pipes 10 forming the loop R are mutually coupled to each other, a strip-shaped support 30 has a structure required separately.

On the other hand, another example of the conventional pipe loop method, as shown in Figures 2 and 3, the connection portion 20 is provided in the side portion of the steel pipe pipes are interconnected by sliding coupling, the lower side of the coupled pipes 10 It has a structure to form a loop (R) by integrally forming the support (H), such as a beam structure.

The connecting portion 20 is formed with guide rails 22 and guide protrusions 24 for coupling between both sides of the outer circumferential surface of the pipes 10, respectively.

However, in the conventional pipe loop method, not only is there a risk of collapse due to detachment of the connected parts of the steel pipe pipes forming the loop by the soil pressure of the ground, but also requires a lot of work time for joining a plurality of reinforcements to the pipes. There was a problem that caused a rise in construction costs.

The present invention has been proposed to solve the above problems in consideration of the above-mentioned problems, and its object is to adopt an unopened tunnel method that can excavate a tunnel without disturbing traffic flow regardless of geology, The present invention provides a tunnel excavation method using a sheet pile so as to satisfy each other's durability and to facilitate an assembly process.

In order to achieve the above object, the present invention inserts a plurality of sheet piles horizontally around a site where underground tunnel structures are to be embedded, and at the same time, interconnects flange portions of the inserted sheet piles to form a loop. And excavating soil in the ground located below the loop to form a tunnel, and embedding the tunnel structure in the interior space of the excavated tunnel.

Another feature of the present invention is to further include the step of removing the inserted pile piles back from the ground to be recycled after the tunnel structure is embedded.

In another feature of the present invention, the sheet pile is formed with hooks to be interconnected to each flange portion.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Tunnel excavation method using a sheet pile according to the present invention, with reference to Figures 4 and 5 and 7, the process inserts a plurality of sheet piles (P) in the ground (G) (S1), the inserted sheet Each flange portion P1 is interconnected to form piles P into one loop R (S2), and the tunnel T is excavated below the inserted sheet piles P (S3). ), The process (S4) for embedding the tunnel structure 40 in the space of the excavated tunnel (T).

In addition, a step S5 may be added in which each sheet pile P forming the loop R is separated and then pulled out of the ground G and drawn out to be recycled.

In more detail, hooks Pa are formed at both flange portions P1 of the sheet piles P so as to facilitate mutual coupling.

Then, the sheet pile (P) is composed of a horizontal coupling portion corresponding to the ceiling, and vertical coupling portion vertically downward on both sides of the horizontal coupling portion, the sheet pile (both sides of the sheet pile ( It has a structure in which P) is integrated by welding or the like.

In addition, although not shown in the drawings, a structure for connecting the flange portions P1 of both sheet piles P to each other by using a separate binding member may be adopted.

Referring to the operation of the present invention in this configuration is as follows.

Tunnel excavation method using the sheet pile (P) of the present invention, first, after the assembly order of the respective processes to push the sheet pile (P) from the lower side to the ground (G) by using hydraulic or pressurized equipment, the sheet pile ( The hook Pa of another sheet pile P is slid in a horizontal direction so that the hook Pa of another sheet pile P is hooked to the hook Pa formed on the flange portion P1 of P).

Subsequently, each sheet pile P is hooked to the hook Pa of the flange portion P1 to be interconnected to form an arcuate or square loop R. As shown in FIG.

At this time, the sheet pile (P) to the ground (G) so that the overall shape of the sheet pile (P) when the combination of each sheet pile (P) has the shape of the tunnel (T) desired by the contractor, regardless of the arch, square or round. Insert it.

After the loop R is formed, the earth and sand located below the loop R is excavated using an excavator, and the tunnel structure 40 made of concrete is embedded in the internal space of the excavated tunnel T.

After the tunnel structure 40 is buried, in order to release the connection structure of each sheet pile P and to separate them, the sheet pile P may be horizontally drawn out to remove the sheet pile P. Allow it to be recycled elsewhere.

At this time, each sheet pile (P) is made of a hook (Pa) in the form of a hook (Pa), so if pulled after gripping one of the ends of the both ends, the hook-connected flange portion (P1) can be separated from each other. .

In addition, as shown in Fig. 6, the structure of the sheet pile P may be one having a structure of another flange portion P2 that can be mutually coupled to each other in addition to the general "Ｕ" shape.

This means that the shape can be freely selected according to the surrounding conditions such as the nature of the geology and the structure of the construction site.

The present invention as described above is to be able to excavate the tunnel in a non-attached manner using a sheet pile in a simple structure, according to the present invention is a sheet pile in a non-adhesive manner without being affected by the lipid By forming the loop of the tunnel by the coupling between the flanges, it is easy to assemble in a simple structure, not only shorten the construction time, but also has a useful effect to improve the durability against earth pressure due to the solid connection structure .

1 is a front view showing an example of a conventional tunnel excavation method.

Figure 2 is a front view showing another example of the conventional tunnel excavation method.

Figure 3 is a perspective view of the main portion coupled to FIG.

Figure 4 is a perspective view showing a tunnel excavation method using a sheet pile according to the present invention.

Figure 5 is a front view showing an example in which the sheet pile of the present invention forms a loop to excavate a tunnel.

Figure 6 is a perspective view showing another example of the sheet pile of the present invention.

Figure 7 is a block diagram showing the process of the tunnel excavation method using the sheet pile of the present invention.

Explanation of symbols on the main parts of the drawings

P: Sheet pile P1: Flange

Pa: Hook G: Underground

T: Tunnel R: Loop

40 tunnel structure

Claims (3)

In the construction method for excavating the tunnel (T) in the ground (G), While inserting a plurality of sheet piles (P) horizontally in the periphery where the tunnel structure (40) of the underground (G) is to be embedded, the flange portions (P1) of each of the inserted sheet piles (P) are mutually Connecting to form a loop (R), Excavating the soil of the ground (G) located below the loop (R) to form a tunnel (T), Tunnel excavation method using a sheet pile, characterized in that it comprises the step of embedding the tunnel structure 40 in the interior space of the tunnel (T) completed the excavation. The method according to claim 1, further comprising a step of detaching the inserted sheet piles (P) from the ground (G) to be recycled after the tunnel structure (40) is embedded. Tunnel excavation method. The method according to claim 1, wherein the sheet pile (P) is a tunnel excavation method using a sheet pile, characterized in that the hook (Pa) is formed to be interconnected to each flange portion (P1).